EP0262340B2

EP0262340B2 - Optical ribbon cable with multiple elements

Info

Publication number: EP0262340B2
Application number: EP87111336A
Authority: EP
Inventors: Masaaki Yokohama Works Nakasuji
Original assignee: Sumitomo Electric Industries Ltd
Current assignee: Sumitomo Electric Industries Ltd
Priority date: 1986-08-05
Filing date: 1987-08-05
Publication date: 2000-07-19
Anticipated expiration: 2007-08-05
Also published as: AU7653687A; EP0262340B1; CA1301509C; KR880003203A; EP0262340A2; AU595632B2; EP0262340A3; DE3751584D1; DE3751584T3; DE3751584T2; US4828349A

Description

The present invention relates to a novel multicore optical fiber ribbon suitable for high density optical communications and more particularly to a multicore optical fiber ribbon such as a tape-shaped optical coated fiber equipped with a covering layer capable of effectively protecting each optical fiber element and besides easy to handle when such optical fibers are coupled together.
With the recent advance of data communications, there has been required for signal transmission at higher speed. As an example of materialization of such high speed signal transmission technology, the recent practical use of optical communications can be cited. The optical signal transmission has many advantages from the standpoint of communications in that the property of light itself is utilizable for realizing high speed transmission and that optical fibers used as transmission lines are lightweight and little affected by magnetic or electric field. However, such an optical fiber is still required for increasing the capacity of signal transmission and, under the circumstances, there have been proposed various kinds of optical fibers for signal transmission.
A multicore optical fiber ribbon is one of the results realized under such circumstances. The multicore optical fiber ribbon, which is formed by integrating fiber elements as optical waveguides with a covering layer common to them, is now spotlighted as what is capable of realizing high density signal transmission with simple care in handling.
Fig. 1 is a sectional view showing the typical structure of a multicore optical fiber ribbon of the sort aforementioned, wherein glass fibers 1 for optical transmission respectively covered with covering layers 2 are further equipped with a common covering layer 3 to form a tape-shaped optical coated fiber.
In the prior art, the formed=said covering layers 2 and 3 are formed of, for example, ultraviolet-curing urethane acrylate.
When the multicore optical fiber ribbon is coupled to another member, e.g., an ordinary single core optical fiber or another multicore optical fiber ribbon, however, the form of a tape is difficult to handle and further the problem of transmission loss resulting from the connection of both also arises. In consequence, the common covering layer 3 must be removed to handle each element together.
On the other hand, the glass fibers without the covering layer suffer from insufficient strength and may cause trouble such as breakage. Thus, when each element is handled, it is prerequisite to remove the common covering layer 3 of the multicore optical fiber ribbon in such a manner that the covering layer 2 of each element perfectly remaines as it is and is also undamaged.
In the case of the conventional multicore optical fiber ribbon, however, the covering layers 2 and the common covering layer 3 are made of the same material. Even if they are not bonded chemically but bonded merely under pressure, it is hardly possible to remove only the common covering layer 3 while the covering layer of each optical fiber is left unremoved completely.
In consequence, not only high degree of skill but also many workhours have been required to couple multicore optical fiber ribbons.
Another known arrangement is to form a covering layer 2 of thermosetting sillicone resin on each optical fiber l and then form a covering layer 3 of nylon common to the optical fibers, in order to provide a multicore optical fiber ribbon. The operation of removing the common covering layer 3 from the multicore optical fiber ribbon of that type is considerably easy because the covering layer 3 is relatively readily peeled off the covering layers 2.
However, because the mechanical strength of the thermosetting silicone resin used for the covering layer 2 of the optical fiber thus constructed is extremely low, the covering layer of each optical fiber element after the removal of the common covering layer can not withstand rubbing or scratching and thus unsuitable for practical use.
The normal way of removing the common covering layer 3 of the conventional multicore optical fiber ribbon is, for instance, to vertically tear the common covering layer 3 into two pieces from both left- and right-hand ends A, A′ with respect to the section shown in Fig. 1. However, the thickness of the common covering layer 3, excluding its portions respectively penetrating into the gaps between the optical fiber elements l and the covering layers 2, is practically uniform and therefore the common covering layer 3 will not readily be detached by simply pulling the halves thereof in certain directions. Ever if it is attempted to tear the common covering layer into two pieces from cut points made in the edges thereof with a knife and the like, the common covering layer is not always caused to tear in the longitudinal direction of the optical fiber. The removal of the common covering layer of the multicore optical fiber is indeed troublesome work.
A compound fiber ribbon has been known from Journal of Lightwave Technology 1986, p. 335-339 in which the several fibers each have a primary coat of a modified silicone and a buffer coat of silicone, and wherein a common ribbon coat consists of nylon. Narrow gaps have been surrounded by the buffer and ribbon coats.
JP 58-98707 discloses an optical fibre ribbon according to the preamble part of claim 1. According to the known optical fibre ribbon a plurality of optical fibres are laterally fixed and coated with a common coating resin in the form of a tape. A common coating resin is for example nylon which may be removed because a peel layer containing a tetrafluoroethylene-fluororubber copolymer as a base is encompassing each optical fibre element.
With respect to the optical fibre ribbon disclosed by JP 58-98707 it is an object of the invention to additionally weaken the common covering sheath to improve its separation and removal.
This object is solved by the features of claim 1.
More specifically, the multicore optical fiber ribbon according to the present invention comprises a plurality of parallel optical fiber elements respectively equipped with covering layers, a common covering layer used for integrally covering the plurality of optical fiber elements, and a thin peel layer as the outermost layer of each optical fiber element for preventing both covering layers from adhering or pressure welding to each other.
The novel multicore optical fiber ribbon according to the present invention is such that the peel layer is provided as the outermost layer of each optical fiber constituting the multicore optical fiber, so that the common covering layer can readily be peeled from the covering layer of each optical fiber. Accordingly, the common covering layer can readily be removed from the covering layer of each optical fiber without damaging the latter.
Moreover, the peel layer sandwiched between each optical fiber and the common covering layer functions so as to prevent both from press welding to each other and each optical fiber can sufficiently maintain its property by the covering layer of each fiber element.
In view of the function of the common covering layer caused to be torn in its thinned portions first, the thinned portions may be located anywhere to attain the intended purpose as long as the common covering layer is halved with respect to the section. However, since the actual optical fiber is relatively as thin as several millimeters in the maximum dimension and, in consideration of workability during the operation, the common covering layer should be preferably tore at both ends of the plane on which the optical fiber elements are disposed.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a sectional view showing the structure of a conventional multicore optical fiber.
Fig. 2 is a sectional view showing the structure of a multicore optical fiber ribbon.
Figs. 3(a) and 3(b) are sectional views showing the structure of multicore optical fiber ribbons.
Figs. 4(a), 4(b) and 4(c) are sectional views showing the structure of other modified multicore optical fiber ribbons, whereby the present embodiments of the present invention are shown in Figs. 4(a) and 4(c).

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Resin material for use in forming a covering layer on each single core optical fiber should be strong enough to protect the optical fiber and various materials conventionally used to form the protective layer of the optical fiber may be employed. Typical materials include thermoplastic resin such as nylon and ultraviolet-curing resin such as urethane acrylate.
As materials for use in forming a peel layer, use can be made of various resins having thermosetting or photo-setting properties such as ultraviolet-curing properties and easy moldability, and further properties which prevent its adherence and press-welding to a common covering layer or the covering layer of each optical fiber.
The material resins used as the peel layer include peeling agents prepared from ultraviolet-curing or thermosetting silicone resin, or ultraviolet-curing or thermosetting fluorocarbon resin. The silicone or fluorocarbon resin for use in this case is an organic compound containing silicon (Si) or fluorine (F) atoms in each molecule and can be hardened when exposed to heat or light, the hardened resin having excellent peel properties.
The peel layer is less than 20 µm and preferably less than 10 µm thick. The reason for this is that, because the peel layer does not always have the protective function to the fiber element, it should preferably be as thin as possible. Also, if the peel layer is excessively thick, it will exert an unfavorable influence on the transmission characteristics of the fiber element and moreover may be damaged or peeled off as a result of friction or the like. On the contrary, the peel layer should preferably be thick enough to separate the common covering layer from the covering layer of each optical fiber element.
With respect to the bond strength of the peel layer relative to an adjoining layer, i.e., the covering layer of each fiber element or common layer, it does not cause inconvenience whether one is greater than or equal to the other but the bond strength thereof relative to the former should preferably be, if anything, greater. The reason for this is attributed to the fact that, because the peel layer has to be destroyed for the removal of the common covering layer in case the peel layer clings to the common layer, undesirable stress acts on the element then. Also, part of the peel layer thus damaged is allowed to remain on the element side, which will necessitate the additional operation of removing the remnants of the peel layer from the element deprived of the common covering layer.
It should further be understood that the formation of multi-covering layers or peel layers are within the technical scope of the prevent invention.
Referring now to the accompanying drawings, a concrete description will given to a multicore optical fiber ribbon embodying the present invention, which should not be construed as limiting the scope of the present invention.
Fig. 2 is a sectional view showing the construction of a multicore optical fiber ribbon.
As shown in Fig. 2, a plurality of sigle core optical fibers l0 are disposed in parallel on the same plane, each optical fiber being equipped with a covering layer 20, and incorporated in a covering layer 30 common to them in order to form a multicore optical fiber. Each optical fiber l0 is equipped with a peel layer 40 on the outer periphery of the covering layer 20. The optical fiber elements are arranged so that the adjacent peel layers 40 is made contact with each other.
The optical fiber l0 is a glass fiber with 125 µm diameter for optical transmission and the covering layer 20 is made of ultraviolet-curing urethane acrylate, so that a signal core optical fiber with 245 µm diameter is formed.
The optical fiber l0 equipped with the covering layer 20 was further passed through a coating die filled with ultraviolet-curing peel layer material to form the peel layer 40. The die used had a hole diameter of 260 µm, whereas ultraviolet-curing silicone acrylate was used as the peel layer material. As for the ultraviolet curing, a 120 W/cm high pressure mercury vapor lamp was used to apply ultraviolet ray irradiation for about five seconds and an optical fiber element with 251 µm diameter equipped with the peel layer 40 was obtained.
Five optical fiber elements l0 respectively equipped with covering layers 20 and the peel layers 40 were arranged in parallel and incorporated in the common covering layer 30 to form a multicore optical fiber ribbon. The common covering layer 30 was formed by applying ultraviolet-curing urethane acrylate and providing ultraviolet ray irradiation.
The common covering layer 30 of the multicore optical fiber ribbon thus constructed could be removed easily by tearing the left- and right-hand ends of the section shown in Fig. 2 and the covering layer free from damage and having sufficient protective strength was left on each optical fiber element deprived of the common covering layer.
Fig. 3(a) is a sectional view showing the structure of a multicore optical fiber ribbon, wherein like reference characters designate like parts of Fig. 2. The optical fiber was formed of the same material and through the same process as in the case of the multicore optical fiber shown in Fig. 2, except that the upper and lower thickness T_A of the common covering 30 was 0.05 mm, whereas the thickness T_B at the left- and right-hand ends was 0.03 mm.
In the multicore optical fiber ribbon thus constructed, since the peel layer 40 is sandwiched between the protective covering layer 20 of each optical fiber element and the common covering layer 30, both were prevented from adhering or press-welding to each other and the removal of the common covering layer 30 was easy. Moreover, the complete protective layer free from defects was left on each optical fiber deprived of the common covering layer.
Fig. 3(b) shows another modification, wherein the sectional shape of the common covering layer 30 was made rectangular, and wherein the thickness of a portion forming a face perpendicular to the direction in which the inner optical fiber elements were disposed was made substantially thinner than a portion forming a face parallel to the direction in which the inner optical fiber elements were disposed.
Figs. 3(a) and 3(b) show multicore optical fiber ribbons with the adjoining optical fiber elements in contact with each other. The present invention is related to multicore optical fiber ribbons wherein the common covering layer 30 is discontinuous at the gap 50 as shown in Fig. 4(a) instead of a continuous common covering layer between the optical fiber elements as shown in Fig. 4(b). Further, as shown in Fig. 4(c), the gap 60 may be formed in portions between the optical fiber element 10 and the common covering layer 30.
As set forth above, the multicore optical fiber ribbon according to the present invention is supplied with the peel layer for preventing the covering layer provided for each optical fibers and the common covering layer for integrating the optical fibers to form the multicore optical fiber ribbon from press-welding or adhering to each other. Accordingly, even though the common covering layer is removed for connecting purposes, the complete covering layer on each optical fiber is allowed to remain, and the connecting operation can be conducted easily for a short time.
Moreover, the multicore optical fiber ribbon according to the present invention is equipped with the peel layer and the common covering layer, a part of which is made substantially thin. Accordingly, even though the common covering layer is removed for connecting purposes, the complete covering layer on each optical fiber is allowed to remain, and the connecting operation can be conducted easily for a short time.
In consequence, it becomes possible to enlarge the applicability of the multicore optical fiber having numerous merits and such a demerit that a high degree of skill is required for handling. That is, the range of applications of optical communication technology and cosequently the practicability of a large volume of data transmission can be further advanced according to the present invention.

Claims

An optical fibre ribbon comprising

a plurality of elongated optical fibre elements (10) assembled in parallel in one common fibre plane, each optical fibre element (10) being encompassed by an associated cover sheath (20);

a common covering sheath (30) encompassing the assembled plurality of optical fibre elements (10);

a peel layer (40) encompassing the cover sheath (20) of each optical fibre element (10), said peel layer having properties which prevent its adherence to the common cover sheath (30) or to the covering sheath (20) of each optical fibre element (10),
wherein
the fibre elements are assembled in such a way that the peel layers of each pair of neighbouring optical fibre elements and the adjacent common covering sheath (30) delimit a longitudinally extending gap (50, 60), characterised in that the thickness of the peel layer (40) is 20 micrometers or less.
The optical fibre ribbon according to claim 1, characterized in that neighbouring optical fibre elements are abutting each other.
The optical fibre ribbon according to claim 1, characterized in that neighbouring optical fibre elements are separated from each other.
The optical fibre ribbon according to claims 1 to 3, characterized in that the peel layer (40) being formed of photosetting or thermosetting fluorocarbon resin or photosetting or thermosetting silicone resin.